JP4659811B2 - Rotating device - Google Patents

Description

  The present invention relates to a rotating device in which a rotor shaft to which a rotor of an induction motor is fixed rotates at a relatively high speed by the rotational force of the induction motor.

  As an example of a rotating device in which the rotor shaft rotates at a relatively high speed as described above, there is a turbo molecular pump. FIG. 1 is a cross-sectional view showing a configuration example of a turbo molecular pump. The turbo molecular pump includes a rotor shaft 11. The rotor shaft 11 includes a motor rotor 13 of an induction motor 12, targets 15 and 15 of a radial magnetic bearing 14, sensor portions 17 and 17 of a radial displacement sensor 16, and an axial magnetic bearing. Eighteen targets 19, a sensor portion (not shown) of an axial displacement sensor, and the like are fixed integrally.

A rotor (impeller) 64 having a rotary blade 60 and a thread groove 62 is fixed to the upper end of the rotor shaft 11. On the inner surface of the pump casing 66, fixed blades 68 are alternately arranged with the rotary blades 60, and thereby, a blade exhaust portion L that performs exhaust by the interaction of the rotary blades 60 that rotate at high speed and the stationary blades 68 that are stationary. ₁ is configured. In addition, a thread groove spacer 70 is disposed so as to surround the thread groove part 62, and thereby, a thread groove exhaust part L ₂ that performs exhaust by a drag action of the thread groove 62 a of the thread groove part 62 that rotates at high speed is configured. Thus, by providing the thread groove exhaust portion L ₂ on the downstream side of the blade exhaust portion L ₁ , a turbo molecular pump capable of dealing with a wide flow range is obtained.

  The motor rotor 13 of the conventional turbo molecular pump and the axial positioning rotor spacer 20 are in contact with the motor end rings 13b and 13b and the targets 15 and 15 in the axial direction as shown in FIG. A motor end ring 13b for collectively connecting conductors arranged in the core 13a of the motor rotor 13 of the induction motor is disposed, and a pure aluminum casting material is used as a material constituting the motor end ring 13b. The specific gravity, tensile strength, longitudinal elastic modulus, and linear expansion coefficient of pure aluminum generally cast for motor end rings are shown below.

Specific gravity: 2.7
Tensile strength: 68 MPa
Longitudinal elastic modulus: 68.6 MPa
Linear expansion coefficient: 2.4 × 10 ⁻⁵ / ° C.
Therefore, when the rotor is rotated at high speed, the strength of this portion may limit the allowable number of rotations of the rotating body.
JP 2002-286036 A

  In the conventional turbo molecular pump, the motor end ring 13b has a cantilever structure as shown in FIG. 2, and is elastically deformed as shown by a broken line 100 in FIG. Therefore, the end surface of the motor end ring 13b is brought into contact with the end surface of the rotor spacer 20 in order to suppress deformation in the radial direction of the motor end ring 13b. Further, since the deformation is suppressed, the stress acting on this portion can be reduced. However, for example, when a load is applied to the induction motor 12 such as introducing gas into the pump, the motor rotor 13 generates heat. At this time, the motor end ring 13b made of an aluminum material has an expansion coefficient larger than that of the material constituting the other members, so that axial internal stress acts on the motor end ring 13b and the rotor spacer 20. In addition, since the internal stress acts (the motor end ring 13b and the rotor spacer 20 are compressed together), there is a problem in that the natural frequency of the entire rotor is changed and the stable rotation of the rotor is hindered. .

  The present invention has been made in view of the above points, and provides a rotating device in which a rotor rotates stably at high speed rotation and rotates at a relatively high speed by the rotational force of an induction motor with excellent reliability. Objective.

The present invention for solving the above-induction comprises a rotor shaft, a core and disposed within the core of the motor rotor conductors of the motor rotor fixed to the rotor shaft, the motor end ring to connect the conductor A rotor shaft, a target of a radial magnetic bearing disposed on both axial sides of the induction motor rotor of the rotor shaft, and a positioning rotor spacer interposed between the target of the induction motor rotor and the radial magnetic bearing. there a rotating device for Rikai rolling by the rotational force of the induction motor, rotor spacers, fixed small inner diameter the outer diameter is secured to the rotor shaft with a small cylindrical than the outer diameter of the core of the motor rotor And a cover portion having a large inner diameter covering the outer periphery of the motor end ring, and the fixing portion is attached to the rotor shaft. By fixing is engaged, characterized in that it is a structure that covers the outer periphery of the motor end ring cover portion.

As described above, the rotor spacer is composed of a fixed portion and a cover portion, and is configured to cover the outer periphery of the motor end ring with the cover portion by fitting and fixing the fixed portion to the rotor shaft. The deformation of the motor end ring in the radial direction during high-speed rotation can be suppressed, and damage due to the deformation of the motor end ring can be prevented.

In the rotating device according to the present invention, the rotor spacer is in contact with the axial end surface of the core of the motor rotor on the outer peripheral side from the motor end ring.

As described above, since the rotor spacer is in contact with the axial end surface of the motor rotor core on the outer peripheral side from the motor end ring, the axial positioning of the motor core or the like is performed regardless of the motor end ring having a large thermal expansion coefficient. be able to. As a result, the action of internal stress can be suppressed by the thermal expansion of the motor end ring, and the change in the natural frequency of the entire rotor can be suppressed.

According to the present invention, in the rotating device described above, a gap is provided in the axial direction of the rotor shaft between the end of the motor end ring on the core side of the anti-motor rotor and the inner surface of the fixed portion of the rotor spacer , and the anti-motor rotor of the motor end ring is provided. The core side end of the non-contact is characterized in that.

As described above, a gap is provided in the axial direction of the rotor shaft between the end of the motor end ring on the core side of the anti-motor rotor and the inner surface of the fixed portion of the rotor spacer, and the end of the motor end ring on the core side of the anti-motor rotor can is because it is non-contact, to suppress increase in internal stress that by the thermal expansion of the motor end ring, and the change in the natural frequency of the rotor caused thereby.

Further, in the rotating device according to the present invention, a gap is provided in a radial direction of the rotor shaft between the outer peripheral surface of the motor end ring and the inner peripheral surface of the cover portion of the rotor spacer, and the outer peripheral surface of the motor end ring is not in contact. It is characterized by.

  Further, the present invention is characterized in that, in the rotating device, the motor end ring has a cross-sectional shape in which the core side of the motor rotor is thick and the core side of the counter-motor rotor is thin.

  As described above, the amount of deformation due to rotation of the motor end ring can be suppressed by making the cross-sectional shape of the motor end ring tapered.

According to the present invention, the rotor spacer has a cylindrical shape whose outer diameter is smaller than the outer diameter of the core of the motor rotor and has a small inner diameter fixing portion fixed to the rotor shaft and a large inner diameter covering the outer periphery of the motor end ring. Since the outer end of the motor end ring is covered with the cover portion by fitting and fixing the fixed portion to the rotor shaft, the displacement of the motor end ring due to the rotation of the rotor shaft is suppressed. Can prevent breakage, and can provide a rotating device with excellent reliability during high-speed rotation.

  Embodiments of the present invention will be described below with reference to the drawings. 4 is a cross-sectional view showing a configuration example of a rotating body of the rotating device according to the present invention, and FIG. 5 is a partially enlarged view thereof. Here, the rotating body 10 will be described by taking a shaft part assembly of a turbo molecular pump as an example. A rotating body 10 shown in the figure has a rotor shaft 11. A motor rotor 13 of an induction motor is attached to the rotor shaft 11, and radial magnetic bearing targets 15, 15 are arranged on both sides of the motor rotor 13. The rotor spacers 20 and 20 are interposed therebetween and are arranged in the axial direction. The motor rotor 13 has a motor rotor core 13a. A conductor is disposed on the motor rotor core 13a, and motor end rings 13b that collectively connect the conductors are disposed on both sides of the motor rotor core 13a.

  The rotor spacer 20 is a cylindrical body and has an inner diameter space that covers the outer periphery of the motor end ring 13b. In a state where the rotor spacers 20 and 20 are interposed between the motor rotor core 13a and the targets 15 and 15 of the radial magnetic bearings arranged on both sides thereof, the motor rotor core 13a, the rotor spacers 20 and 20, the target 15 of the radial magnetic bearing, 15 and the like are positioned in the axial direction, and the rotor spacers 20 and 20 cover the outer periphery in the radial direction of the motor end ring 13b. That is, one end of the rotor spacers 20, 20 (the end on the side opposite to the motor rotor core 13a) is fitted to the rotor shaft, and the other end contacts the both end surfaces of the motor rotor core 13a in the axial direction on the outer peripheral side of the motor end ring 13b. is doing. A predetermined gap g1 is provided between the end surface of the motor end ring 13b on the side opposite to the motor end ring 13b and the end surface on the inner side of the rotor spacer 20, and the end surface of the motor end ring 13b is not in contact.

  As described above, the gap g1 is provided between the end surface of the motor end ring 13b and the inner surface of the rotor spacer 20, and the motor end ring 13b is not brought into contact with the rotor spacer 20 in the axial direction. The rise and the change in the rotor natural frequency due to the rise can be suppressed. Further, since the rotor spacer 20 covers the outer periphery in the radial direction of the motor end ring 13b, it is possible to suppress radial deformation due to centrifugal force applied to the motor end ring 13b, and damage due to deformation of the motor end ring 13b. Can be prevented. The gap g2 in the radial direction between the motor end ring 13b and the inner surface of the rotor spacer 20 that covers the motor end ring 13b only needs to ensure a gap that allows the rotating body 10 to be assembled.

  The positioning of the motor rotor 13 and the radial magnetic bearing targets 15 and 15 in the axial direction prevents the motor end ring 13b from directly contacting the rotor spacers 20 and 20 so that the rotor spacers 20 and 20 are shown in FIG. Thus, the structure which contacts the motor rotor core 13a by the outer peripheral side of the motor end ring 13b is employ | adopted. Thus, the axial contact is a direct contact between the rotor spacers 20 and 20 and both end faces of the motor rotor core 13a. A silicon steel plate which is a ferromagnetic material is used as a material constituting the motor rotor core 13a. Further, SUS alloy, titanium alloy or the like is suitable for the material constituting the rotor spacer 20. The linear expansion coefficient of SUS alloy and titanium alloy is smaller than the linear expansion coefficient of aluminum, and is relatively close to the linear expansion coefficient of silicon steel sheet, increasing internal stress due to thermal expansion, and the entire rotating body 10. The influence on the natural frequency is small.

FIG. 10 shows materials that can be used for the member that covers the rotor spacer 20, that is, the motor end ring 13b, and their characteristics (specific gravity, tensile strength [MPa], longitudinal elastic modulus [GPa], linear expansion coefficient × 10 ⁻⁵ / ° C.). , Specific strength = tensile strength / specific gravity). As illustrated, SUS304, SUS403, SUS420, SUS630, and TAF6400 can be used as a member (here, the rotor spacer 20) that covers the motor end ring 13b.

  In FIG. 4, a portion indicated by a dotted line 101 indicates that the rotor spacer 20 suppresses deformation in the radial direction of the motor end ring 13b, and thus the rotor spacer 20 itself slightly deforms in the radial direction. Since the rotor spacer 20 itself is slightly deformed in the radial direction in this way, as shown in FIG. 5, the diameter dimension φDs of this portion of the rotor spacer 20 is set to the motor rotor core 13a, the radial magnetic bearing target 15 (see FIG. 4), etc. It is desirable that the other rotating body 10 is formed so as to have a diameter equal to or less than (Ds ≦ Dc) with respect to the outer diameter φDc.

  FIG. 6 is a cross-sectional view showing another configuration example of the rotating body of the rotating device according to the present invention, and FIG. 7 is a partially enlarged view thereof. As shown in the drawing, a member having a structure covering the motor end ring 13b, that is, the rotor spacer 20, is in axial contact with both end surfaces of the motor rotor core 13a on the inner peripheral side from the motor end ring 13b. Further, an inner diameter space that covers the outer periphery of the end of the motor end ring 13b is formed in the vicinity of the end of the rotor spacer 20 on the side opposite to the motor rotor core 13a. In a state where the rotor spacer 20 is interposed between the motor rotor core 13a and the targets 15 and 15 of the radial magnetic bearings arranged on both sides thereof, the motor rotor core 13a, the rotor spacers 20 and 20, the targets 15 and 15 of the radial magnetic bearing, etc. The rotor spacers 20 and 20 cover the outer periphery of the end of the motor end ring 13b on the side opposite to the motor rotor core 13a. A predetermined gap g1 is provided between the end surface of the motor end ring 13b on the side opposite to the motor rotor core 13a and the inner end surface of the rotor spacer 20.

  As described above, the gap g1 is provided between the end surface of the motor end ring 13b and the inner end surface of the rotor spacer 20, and the motor end ring 13b is not brought into contact with the rotor spacer 20 in the axial direction. It is possible to suppress an increase in stress and a change in the natural frequency of the rotor resulting therefrom. Further, since the rotor spacer 20 covers the outer periphery of the end of the motor end ring 13b on the side opposite to the motor rotor core 13a, it is possible to suppress radial deformation due to centrifugal force applied to the motor end ring 13b. Damage due to deformation of the ring 13b can be prevented.

  In FIG. 6, a portion indicated by a dotted line 102 indicates that the rotor spacer 20 suppresses deformation in the radial direction of the motor end ring 13b, and thus the rotor spacer 20 itself is slightly deformed in the radial direction. Since the rotor spacer 20 itself is slightly deformed in the radial direction in this way, as shown in FIG. 7, the diameter dimension φDs of the rotor spacer 20 in this portion is set to the motor rotor core 13a, the radial magnetic bearing target 15 (see FIG. 6), etc. It is desirable that the other rotating body 10 is formed so as to have a diameter equal to or less than (Ds ≦ Dc) with respect to the outer diameter φDc.

  FIG. 8 is a cross-sectional view showing a part of another configuration example of the rotating body of the rotating device according to the present invention. As shown in the drawing, the motor end ring 13b has a tapered shape with a cross section that is thicker on the motor rotor core 13a side and thinner on the opposite side. The rotor spacer 20 is formed with a taper-shaped space covering the outer periphery of the motor end ring 13b having a taper-shaped cross section. The motor end ring 13b is disposed in the tapered space, and the rotor spacer 20 covers the outer periphery of the motor end ring 13b. A predetermined gap g1 is provided between the end surface of the motor end ring 13b on the side opposite to the motor rotor core 13a and the inner end surface of the rotor spacer 20.

  By making the cross-sectional shape of the motor end ring 13b into a tapered structure as described above, it is possible to reduce the amount of deformation due to the centrifugal force caused by the rotation of the motor end ring 13b. Further, since the cross-sectional area of the base portion of the motor end ring 13b increases, the structural strength of the motor end ring 13b itself can be increased. Further, the motor end ring 13b collectively connects the secondary current flowing through the conductor in the motor rotor core 13a. If the conductive cross-sectional area of the motor rotor core 13a (volume of the motor rotor core 13a) is equivalent to that in FIG. 2, the electric resistance values are the same and there is no influence on the performance of the induction motor. The shape is arbitrary as long as the conductive cross-sectional area (volume of the motor end ring 13b) can be kept the same.

  As described above, the gap g1 is provided between the end surface of the motor end ring 13b and the inner end surface of the rotor spacer 20, and the motor end ring 13b is not brought into contact with the rotor spacer 20 in the axial direction. It is possible to suppress an increase in stress and a change in the natural frequency of the rotor resulting therefrom. Further, since the rotor spacer 20 covers the outer periphery in the radial direction of the motor end ring 13b, it is possible to suppress radial deformation due to centrifugal force applied to the motor end ring 13b, and damage due to deformation of the motor end ring 13b. Can be prevented. The gap g2 in the radial direction between the motor end ring 13b and the inner surface of the rotor spacer 20 that covers the motor end ring 13b only needs to ensure a gap that can be assembled.

  FIG. 9 is a cross-sectional view showing a part of another configuration example of the rotating body of the rotating device according to the present invention. As shown in the drawing, a member having a structure covering the motor end ring 13b, that is, the rotor spacer 20, is in axial contact with both end surfaces of the motor rotor core 13a on the inner peripheral side from the motor end ring 13b. The motor end ring 13b has a tapered shape in which the cross section is thick on the motor rotor core 13a side and thin on the opposite side. A space having an inner diameter covering the outer periphery of the end of the motor end ring 13b is formed in the vicinity of the end of the rotor spacer 20 on the side opposite to the motor rotor core 13a. With the rotor spacer 20 interposed between the motor rotor core 13a and the target 15 of the radial magnetic bearing, the rotor spacer 20 covers the outer periphery of the end of the motor end ring 13b on the side opposite to the motor rotor core 13a. Even if comprised in this way, there exists an effect similar to the rotary body of the structure shown in FIG.

  As an application example of the rotating device having the rotating body 10, a turbo molecular pump as shown in FIG. 1 in which the rotor is driven at a rotational speed of tens of thousands of revolutions can be considered. It can also be applied to a molecular drag pump or the like that exhausts the gas. Moreover, although the magnetic bearing was demonstrated to the example as a bearing, mechanical bearings other than a magnetic bearing, a dynamic pressure bearing, etc. can also be used.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the technical idea described in the claims and the specification and drawings. Is possible. For example, in the above example, the member that covers the outer periphery of the motor end ring 13b is provided integrally with the rotor spacer 20. However, the member that covers the outer periphery of the motor end ring 13b may be separated from the rotor spacer 20.

It is sectional drawing which shows the structural example of a turbo-molecular pump. It is sectional drawing which shows the structural example of the shaft assembly of a turbo-molecular pump. FIG. 3 is a partially enlarged view of FIG. 2. It is sectional drawing which shows the structural example of the rotary body of the rotating apparatus which concerns on this invention. FIG. 5 is a partially enlarged view of FIG. 4. It is sectional drawing which shows the structural example of the rotary body of the rotating apparatus which concerns on this invention. FIG. 7 is a partially enlarged view of FIG. 6. It is sectional drawing which shows a part of other structural example of the rotary body of the rotating apparatus which concerns on this invention. It is sectional drawing which shows a part of other structural example of the rotary body of the rotating apparatus which concerns on this invention. It is a figure which shows the material and characteristic which are used for the member which covers a motor end ring.

Explanation of symbols

10 Rotating body 11 Rotor shaft
DESCRIPTION OF SYMBOLS 12 Induction type motor 13 Motor rotor 13a Motor rotor core 13b Motor end ring 15 Target of radial magnetic bearing 20 Rotor spacer

Claims (5)

A rotor shaft, and the induction motor rotor comprising a conductor disposed within the core of the core and the motor rotor of the motor rotor fixed to the rotor shaft, the motor end ring to connect the conductor, the induction of the rotor shaft A radial magnetic bearing target disposed on both axial sides of the motor rotor, and a positioning rotor spacer interposed between the induction motor rotor and the radial magnetic bearing target . a rotating device that Rikai rolling by the rotational force,
The rotor spacer has a cylindrical shape whose outer diameter is smaller than the outer diameter of the core of the motor rotor and has a small inner diameter fixing portion fixed to the rotor shaft, and a large inner diameter covering portion that covers the outer periphery of the motor end ring. The rotating device is configured to cover the outer periphery of the motor end ring with the covering portion by fitting and fixing the fixing portion to the rotor shaft . The rotating device according to claim 1,
The rotating device is characterized in that the rotor spacer is in contact with the axial end surface of the core of the motor rotor on the outer peripheral side from the motor end ring. The rotating device according to claim 1 or 2 ,
The motor end ring gap in the axial direction of the rotor shaft between the inner surface of the fixed portion of the rotor spacer and core side end of the reaction the motor rotor is disposed in the core side end of the reaction the motor rotor of the motor end ring Is a non-contact rotating device. The rotating device according to any one of claims 1 to 3,
A rotating device characterized in that a gap is provided in the radial direction of the rotor shaft between the outer peripheral surface of the motor end ring and the inner peripheral surface of the cover portion of the rotor spacer, and the outer peripheral surface of the motor end ring is non-contact. . The rotating device according to any one of claims 1 to 4 ,
The rotating device according to claim 1, wherein the motor end ring has a tapered shape in which the core side of the motor rotor is thick and the core side of the motor rotor is thin.

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